CN218634355U - Take human response lamp of 433 communications - Google Patents

Abstract

The utility model provides a human body induction lamp with 433 communication, which comprises a lamp body, an induction probe and a main lamp panel; the induction probe comprises a human body induction device, a 433 wireless transmission module and a first main control circuit; the human body sensing device is used for outputting a first electric signal to the first main control circuit when a human body is sensed, and the first main control circuit is used for controlling 433 the wireless transmitting module to output the first electric signal; be provided with 433 wireless receiving module on the main lamp plate, and main lamp plate accessible 433 wireless receiving module receives the first signal of telecommunication of inductive probe output to control the lamp body and light. The utility model discloses install the inductive probe and the main lamp panel of human response lamp independently to connect both through the wireless communication mode, make inductive probe avoid receiving the phenomenon of the interference of lamp plate because of loaded down with trivial details wiring, still enlarged the response scope of human response lamp simultaneously.

Description

Take human response lamp of 433 communications

Technical Field

The utility model belongs to the technical field of the response lamp, especially, relate to a take human response lamp of 433 communications.

Background

The human body induction lamp is used for inducing a human body to control the LED lamp body to emit light. When people or objects with temperature enter the sensing range of the human body sensing lamp, the built-in sensing module can output a high-level pulse signal or a high-level delay signal, and the output sensing pulse or the delay signal can directly drive the LED lamp indicating lamp and the LED illuminating lamp.

In the current market, a lamp body of the human body induction lamp can induce a human body and light the lamp body only by externally connecting an induction probe, the lamp body and the induction probe are connected together, so that the use place of the human body induction lamp is greatly limited, inconvenience is brought to a user due to complicated wiring of the induction lamp, and the installation is also difficult in the aspect of attractiveness. In addition, when the probe and the main control lamp plate are assembled together, the probe is easily interfered by the main lamp plate to cause false triggering, so that the human body induction lamp does not sense a human body and is also lighted, and the consumption of electric quantity is caused.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a take human response lamp of 433 communications, aim at the inductive probe and the main lamp board independent erection with human response lamp to connect both through 433 wireless communication module, with the response scope of expanding human response lamp.

In order to achieve the above object, the utility model provides a take human response lamp of 433 communication, it includes:

a lamp body;

the induction probe comprises a human body induction device, a 433 wireless transmission module and a first main control circuit;

the output end of the human body induction device is connected with the first input end of the first main control circuit, and the first output end of the first main control circuit is connected with the input end of the 433 wireless transmission module;

the human body sensing device is used for outputting a first electric signal to the first main control circuit when a human body is sensed, and the first main control circuit is used for controlling the 433 wireless transmission module to output the first electric signal;

the wireless receiving module comprises a main lamp panel, wherein a 433 wireless receiving module is arranged on the main lamp panel;

the main lamp panel is provided with a signal output end which is used for being connected with the controlled end of the lamp body;

the main lamp panel receives the first electric signal output by the inductive probe through the 433 wireless receiving module and controls the lamp body to light.

Optionally, the inductive probe further comprises:

a battery for outputting a battery voltage;

the input end of the first power management module is connected with the first output end of the battery, the first output end of the first power management module is connected with the power end of the first main control circuit, the second output end of the first power management module is connected with the power end of the human body induction device, and the third output end of the first power management module is connected with the power end of the 433 wireless transmitting module;

the first power management module is used for converting the battery voltage into a stable voltage and supplying the stable voltage to the first main control circuit, the human body induction device and the 433 wireless transmission module to work

Optionally, the inductive probe further comprises:

the input end of the indicator light is connected with the second output end of the first main control circuit;

the input end of the low-voltage detection circuit is connected with the second output end of the battery, and the output end of the low-voltage detection circuit is connected with the second input end of the first main control circuit;

the low-voltage detection circuit is used for receiving the battery voltage of the battery and converting the battery voltage into a second electric signal according to the battery voltage to output;

and the first main control circuit is also used for receiving the second electric signal and controlling the indicator light to flicker when the voltage value of the battery is judged to be lower than the preset value according to the second electric signal.

Optionally, the main lamp panel further includes:

a first input end of the second main control circuit is connected with an output end of the 433 wireless receiving module, and an output end of the second main control circuit is a signal output end of the main lamp panel;

the second master control circuit is used for receiving the first electric signal of the 433 wireless receiving module and controlling the lamp body to light according to the first electric signal.

Optionally, the main lamp panel further includes:

the input end of the second power management module is connected with a power supply, and the output end of the second power management module is connected with the power supply end of the second main control circuit and the power supply end of the 433 wireless receiving module;

and the second power supply management module is used for converting the voltage of the power supply into a stable voltage and supplying the stable voltage to the second main control circuit and the 433 wireless receiving module for working.

Optionally, the body sensing device is a body pyroelectric infrared sensor.

Optionally, the number of inductive probes is plural.

Optionally, the inductive probe further comprises:

the input end of the first key input circuit is connected with the third input end of the first main control circuit;

the first keying input circuit is used for outputting a code matching signal;

the first master control circuit is further used for receiving the code matching signals and controlling the 433 wireless transmitting module to output the code matching signals so as to complete connection between the induction probe and the main lamp panel.

Optionally, the main lamp panel further includes:

the input end of the second key input circuit is connected with the second input end of the second main control circuit;

the second keying input circuit is used for outputting clear code signals;

and the second master control circuit is also used for receiving the clear code signal and controlling the main lamp panel to be disconnected with the inductive probe.

The utility model provides a human body induction lamp with 433 communication, which comprises a lamp body, an induction probe and a main lamp panel; the induction probe comprises a human body induction device, a 433 wireless transmission module and a first main control circuit; the human body sensing device is used for outputting a first electric signal to the first main control circuit when a human body is sensed, and the first main control circuit is used for controlling 433 the wireless transmitting module to output the first electric signal; be provided with 433 wireless receiving module on the main lamp plate, and main lamp plate accessible 433 wireless receiving module receives the first signal of telecommunication of inductive probe output to control the lamp body and light. The utility model discloses install the inductive probe and the main lamp panel of human response lamp independently to connect both through the wireless communication mode, make inductive probe avoid receiving the phenomenon of the interference of lamp plate because of loaded down with trivial details wiring, still enlarged the response scope of human response lamp simultaneously.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic diagram of functional modules of a human body induction lamp with 433 communication according to the present invention;

fig. 2 is a functional block diagram of the induction probe of the human body induction lamp with 433 communication according to the present invention;

fig. 3 is a functional module schematic diagram of the main lamp panel of the human body induction lamp with 433 communication according to the present invention;

fig. 4 is a schematic circuit diagram of the sensing probe of the human body sensing lamp with 433 communication according to the present invention;

fig. 5 is a schematic diagram of a circuit structure of the main lamp panel of the body induction lamp with 433 communication according to the present invention.

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, back, 8230; \8230;) are provided in the embodiments of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the attached drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In addition, if appearing throughout the text, "and/or" is meant to include three juxtaposed aspects, taking "a and/or B" as an example, including either the a aspect, or the B aspect, or both the a and B aspects. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

It is understood that the functions of the human body sensing lamp are diversified along with the development of technologies. In the existing market, the lamp body of a common human body induction lamp needs to be assembled with a main control lamp plate, so that people near the lamp body can be induced and the lamp body can be lightened. Even if the lamp body and the main control lamp panel are not installed together, the lamp body still needs to be connected with an external induction probe to sense a human body and enable the lamp body to light, so that the use place of the human body induction lamp is greatly limited, inconvenience is brought to a user due to complicated wiring of the induction lamp, and the lamp is also a difficult problem in the aspect of attractive installation. In addition, when the probe and the main control lamp plate are assembled together, the probe is easily interfered by the lamp plate to cause false triggering, so that the human body induction lamp does not sense people and is also triggered to light, and the consumption of electric quantity is caused.

Therefore, the utility model provides a take human response lamp of 433 communication, include:

a lamp body 30;

the induction probe 10 comprises a human body induction device 11, a 433 wireless transmission module 13 and a first main control circuit 12;

the output end of the human body induction device 11 is connected with the first input end of the first main control circuit 12, and the first output end of the first main control circuit 12 is connected with the input end of the 433 wireless transmission module 13;

the human body sensing device 11 is configured to output a first electrical signal to the first main control circuit 12 when sensing a human body, and the first main control circuit 12 is configured to control the 433 wireless transmitting module 13 to output the first electrical signal;

the wireless receiving module comprises a main lamp panel 20, wherein a 433 wireless receiving module 21 is arranged on the main lamp panel 20;

the main lamp panel 20 has a signal output end for connecting with a controlled end of the lamp body 30;

the main lamp panel 20 receives the first electrical signal output by the inductive probe 10 through the 433 wireless receiving module 21, and controls the lamp body 30 to light.

Optionally, the human body sensing device may be implemented by a pyroelectric sensor, the pyroelectric sensor includes two sensing elements therein, when a human body is in a preset range monitored by the pyroelectric sensor, an infrared signal emitted by the human body triggers the pyroelectric sensor, the two sensing elements inside generate electric charges correspondingly, an electric potential difference is formed along with movement of the electric charges, and the electric potential difference is amplified by a control unit inside the pyroelectric sensor and then output in the form of an action sensing signal; it should be understood that, when a person is in the sensing range of the pyroelectric sensor and acts, the human body correspondingly sends out an infrared signal, and the pyroelectric sensor outputs a first telecommunication signal by receiving the infrared signal.

Optionally, in another embodiment, the human body sensing device may be implemented by using a microwave sensor, the microwave sensor includes a transmitter and a receiver therein, the transmitter is configured to transmit millimeter waves to collect microwave signals emitted by a human body within a preset range of the microwave sensor, and meanwhile, return corresponding motion sensing signals to the receiver of the microwave module in the air, and the microwave sensor outputs the motion sensing signals in a low-level or high-level manner; it should be understood that when a person moves within the sensing range of the microwave sensor, the person correspondingly sends out a microwave signal corresponding to the moving frequency, and the microwave sensor outputs a first telecommunication signal by receiving the microwave signal.

In particular, in practical application, the sensing probe can be installed at a position which a user needs to sense, even at a position which is separated from the main lamp panel; when a user is in the sensing range of the sensing probe, a human body sensing device arranged in the sensing probe outputs an electric signal to a first main control circuit when sensing a human body, and the first main control circuit controls a 433 wireless transmitting module arranged in the human body sensing lamp to output the first electric signal; through wireless transmission, the 433 wireless receiving module that establishes in the main lamp plate receives this first signal of telecommunication, and main lamp plate passes through signal output terminal output control signal simultaneously to the lamp body light of control rather than being connected, even if inductive probe and main lamp plate partition wall installation, also can reach the effect of response light. If the induction probe is installed outside the bedroom door, the induction lamp can be turned on in advance before a user enters the bedroom, and the phenomenon that the induction lamp delays is avoided. Moreover, inductive probe and master control lamp plate separately assemble, and inductive probe does not receive the phenomenon that the mistake triggered appears because of the interconnect with the main lamp plate in the interference, avoids human response lamp to appear the mistake and triggers and the condition of lighting a lamp.

The utility model provides a human body induction lamp with 433 communication, which comprises a lamp body 30, an induction probe 10 and a main lamp panel 20; the induction probe 10 comprises a human body induction device 11, a wireless transmitting module 13 of 433 and a first main control circuit 12; the human body sensing device 11 is used for outputting a first electric signal to the first main control circuit 12 when sensing a human body, and the first main control circuit 12 is used for controlling 433 the wireless transmitting module 13 to output the first electric signal; the main lamp panel 20 is provided with a 433 wireless receiving module 21, and the main lamp panel 20 can receive the first electrical signal output by the inductive probe 10 through the 433 wireless receiving module 21, and control the lamp body 30 to light. The utility model discloses install the inductive probe 10 and the main lamp panel 20 of human response lamp independently, respectively set up a 433 wireless transmitting module and 433 wireless receiving module in inductive probe 10 and the main control panel inside to realize the wireless transmission of both signals, its transmission process has saved the loaded down with trivial details of wiring between inductive probe 10 and the main control panel, reaches the effect that the inductive lamp installation cost is low, and transmission frequency stability is high; meanwhile, the induction range of the human body induction lamp is expanded.

In this embodiment, referring to fig. 2, the inductive probe 10 further includes:

a battery 14, the battery 14 for outputting a battery voltage;

a first power management module 15, wherein an input terminal of the first power management module 15 is connected to a first output terminal of the battery 14, a first output terminal of the first power management module 15 is connected to a power terminal of the first main control circuit 12, a second output terminal of the first power management module 15 is connected to a power terminal of the human body sensor 11, and a third output terminal of the first power management module 15 is connected to a power terminal of the 433 wireless transmission module 13;

the first power management module 15 is configured to convert the battery voltage into a stable voltage and supply the stable voltage to the first main control circuit 12, the human body sensing device 11, and the wireless transmitting module 433 to operate.

It will be appreciated that the positive and negative poles of the battery 14 together form the output terminals of the battery 14;

specifically, the first power management module 15 is configured to improve utilization of the battery 14, prevent overcharge and overdischarge of the battery 14, prolong a service life of the battery 14, and monitor a state of the battery 14. Specifically, the battery 14 outputs a voltage to the first power management module 15, and the first power management module 15 outputs a stable voltage to provide power for the first main control circuit 12, the human body sensing device 11 and the 433 wireless transmission module 13 after the voltage conversion processing of the first power management module 15, so as to maintain the operation of the first main control circuit 12, the human body sensing device 11 and the 433 wireless transmission module 13. For example: the voltage output by the battery 14 is 3V, and is converted into a 2.5V power supply voltage by the first power management module 15, and the 2.5V power supply voltage is respectively output to the first main control circuit 12, the human body sensing device 11 and the wireless transmitting module 433.

In this embodiment, referring to fig. 2, the inductive probe 10 further includes:

an indicator light 17, wherein an input end of the indicator light 17 is connected with a second output end of the first main control circuit 12;

the input end of the low voltage detection circuit 16 is connected to the second output end of the battery 14, and the output end of the low voltage detection circuit 16 is connected to the second input end of the first main control circuit 12;

the low voltage detection circuit 16 is configured to receive a battery voltage of the battery 14 and convert the battery voltage into a second electrical signal according to the battery voltage for outputting;

the first main control circuit 12 is further configured to receive the second electrical signal, and control the indicator light 17 to blink when it is determined that the voltage value of the battery 14 is lower than the preset value according to the second electrical signal.

It is understood that the inductive probe 10 can also perform low voltage detection on the battery 14 through the low voltage detection circuit 16, specifically, an input terminal of the low voltage detection circuit 16 is connected to a second output terminal of the battery 14, receives a battery voltage signal output by the battery 14, and outputs a second electrical signal according to the voltage signal of the battery 14; the second input end of the first main control circuit 12 receives the second electrical signal, and outputs a control signal through the second output end when the voltage value of the battery 14 is judged to be lower than the preset value, so as to control the indicator light 17 to flash. For example, when the battery voltage of the inductive probe 10 is lower than 2.5V, the indicator light 17 blinks at a speed of 1S to indicate a power failure, so as to indicate to the user that the battery 14 of the inductive probe 10 is in a low state.

In this embodiment, referring to fig. 3, the main lamp panel 20 further includes:

a first input end of the second main control circuit 22 is connected to an output end of the 433 wireless receiving module 21, and an output end of the second main control circuit 22 is a signal output end of the main lamp panel 20;

the second main control circuit 22 is configured to receive the first electrical signal of the 433 wireless receiving module 21, and control the lamp body 30 to light according to the first electrical signal.

It is understood that the second control circuit 22 is a main control part of the main light panel 20; when the 433 wireless receiving module 21 in the main light panel 20 receives the first electrical signal, the first electrical signal is output to the input end of the second main control circuit 22 through the output end, the output end of the second main control circuit 22 is the signal output end of the main light panel 20, and the second main control circuit 22 controls the light of the lamp body 30 by outputting the first electrical signal to the controlled end of the lamp body 30.

In this embodiment, referring to fig. 3, the main lamp panel 20 further includes:

a second power management module 23, an input end of the second power management module 23 is connected to a power supply, and an output end of the second power management module 23 is connected to a power end of the second main control circuit 22 and a power end of the 433 wireless receiving module 21;

the second power management module 23 is configured to convert a voltage of a power supply into a stable voltage and supply the stable voltage to the second main control circuit 22 and the 433 wireless receiving module 21 for operation.

It can be understood that the second power management module 23 is used for stabilizing the voltage of the power supply and preventing the overvoltage from damaging 433 the wireless receiving module 21 and the second main control circuit 22. Specifically, the power supply outputs a voltage to the second power management module 23, and the second power management module 23 outputs a stable voltage to provide power for the second main control circuit 22 and the 433 wireless receiving module 21 through the voltage conversion processing of the second power management module 23, so as to maintain the operation of the second main control circuit 22 and the 433 wireless receiving module 21.

In this embodiment, referring to fig. 1, the human body sensing device 11 is a human body pyroelectric infrared sensor.

It can be understood that when a person acts in the sensing range of the pyroelectric sensor, the human body correspondingly sends out an infrared signal, and the pyroelectric sensor outputs a first telecommunication signal by receiving the infrared signal.

In another embodiment, the number of the inductive probes 10 is plural.

It will be appreciated that the number of the sensing probes 10 can be plural and can be placed in different orientations as desired by the user in order to ensure that the body can be sensed in a plurality of orientations and the lamp body 30 is triggered to emit light. For example, there are three inductive probes 10, which are a first inductive probe 10, a second inductive probe 10 and a third inductive probe 10, respectively, and the three inductive probes 10 are respectively placed on the door of the bedroom, on the ceiling of the bedroom and in the corner of the bedroom; in this embodiment, the three inductive probes 10 are distributed, so that the inductive range is expanded, the three inductive probes 10 can sense people as much as possible, and the phenomenon that the lamp body 30 cannot be triggered to emit light due to the fact that the inductive range of only one inductive probe 10 is too small is avoided.

In this embodiment, referring to fig. 4, the inductive probe 10 further includes:

a first key input circuit 18, wherein an input end of the first key input circuit 18 is connected with a third input end of the first main control circuit 12;

the first keying input circuit 18 is used for outputting a code matching signal;

the first main control circuit 12 is further configured to receive the code matching signal and control the 433 wireless transmitting module 13 to output the code matching signal, so as to complete connection between the inductive probe 10 and the main lamp panel 20.

It can be understood that the first key input circuit 18 arranged in the inductive probe 10 is the first key, when the user presses the first key, the first key outputs a pair code signal, it can be understood that the pair code signal is a transmitting signal which can be used for being matched and connected with the main lamp panel 20, the first main control circuit 12 receives the pair code signal through the third input end, the wireless transmitting module 433 outputs the pair code signal, and the main lamp panel 20 receives the pair code signal through the wireless receiving module 433 21, so as to complete the wireless connection between the inductive probe 10 and the main lamp panel 20. For example, in 10S that main lamp panel 20 connects to the power, the user presses first keying thrice and can send the code matching signal and carry out the code matching connection with main lamp panel 20 for a short time, and each main lamp panel 20 can be connected with 3 inductive probes 10 simultaneously.

In this embodiment, referring to fig. 5, the main lamp panel 20 further includes:

a second key input circuit 24, wherein an input terminal of the second key input circuit 24 is connected to a second input terminal of the second master control circuit 22;

the second keying input circuit 24 is used for outputting a clear code signal;

the second main control circuit 22 is further configured to receive the clear code signal and control the main lamp panel 20 to be disconnected from the inductive probe 10.

It will be appreciated that the second key input circuit 24 provided in the main light panel 20 is a second key,

when the user presses the secondary key, the secondary key outputs a clear code signal, and it can be understood that the clear code signal is a signal that can be used to disconnect from the inductive probe 10, and the second main control circuit 22 receives the clear code signal through the second input terminal, and controls the main lamp panel 20 to disconnect from the inductive probe 10.

For example, the user can complete the clear code operation by pressing the second key 5S for a long time, and at this time, the main lamp panel 20 is disconnected from the inductive probe 10.

The above embodiments are only preferred embodiments of the present invention, and do not limit the scope of the present invention, and all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings or directly or indirectly applied to other related technical fields are included in the patent protection scope of the present invention.

Claims (9)

1. A human body induction lamp with 433 communication, comprising:

a lamp body;

the induction probe comprises a human body induction device, a 433 wireless transmission module and a first main control circuit;

the output end of the human body induction device is connected with the first input end of the first main control circuit, and the first output end of the first main control circuit is connected with the input end of the 433 wireless transmission module;

the human body sensing device is used for outputting a first electric signal to the first main control circuit when a human body is sensed, and the first main control circuit is used for controlling the 433 wireless transmission module to output the first electric signal;

the wireless receiving module comprises a main lamp panel, wherein a 433 wireless receiving module is arranged on the main lamp panel;

the main lamp panel is provided with a signal output end which is used for being connected with the controlled end of the lamp body;

the main lamp panel receives the first electric signal output by the inductive probe through the 433 wireless receiving module and controls the lamp body to light.

2. The body induction lamp with 433 communication of claim 1, wherein said induction probe further comprises:

a battery for outputting a battery voltage;

the input end of the first power management module is connected with the first output end of the battery, the first output end of the first power management module is connected with the power end of the first master control circuit, the second output end of the first power management module is connected with the power end of the human body induction device, and the third output end of the first power management module is connected with the power end of the 433 wireless transmission module;

and the first power management module is used for converting the battery voltage into a stable voltage and then supplying the stable voltage to the first main control circuit, the human body induction device and the 433 wireless transmission module for working.

3. The body induction lamp with 433 communication of claim 2, wherein said induction probe further comprises:

the input end of the indicator light is connected with the second output end of the first main control circuit;

the input end of the low-voltage detection circuit is connected with the second output end of the battery, and the output end of the low-voltage detection circuit is connected with the second input end of the first main control circuit;

the low-voltage detection circuit is used for receiving the battery voltage of the battery and converting the battery voltage into a second electric signal according to the battery voltage to output;

and the first main control circuit is also used for receiving the second electric signal and controlling the indicator light to flicker when the voltage value of the battery is judged to be lower than the preset value according to the second electric signal.

4. The body-sensing lamp with 433 communication of claim 1, wherein the main lamp panel further comprises:

a first input end of the second main control circuit is connected with an output end of the 433 wireless receiving module, and an output end of the second main control circuit is a signal output end of the main lamp panel;

and the second main control circuit is used for receiving the first electric signal of the 433 wireless receiving module and controlling the lamp body to light according to the first electric signal.

5. The body-sensing lamp with 433 communication of claim 4, wherein the main light panel further comprises:

the input end of the second power management module is connected with a power supply, and the output end of the second power management module is connected with the power supply end of the second main control circuit and the power supply end of the 433 wireless receiving module;

and the second power supply management module is used for converting the voltage of the power supply into a stable voltage and supplying the stable voltage to the second main control circuit and the 433 wireless receiving module for working.

6. The body-sensing lamp with 433 communication of claim 1, wherein the body-sensing device is a pyroelectric infrared sensor.

7. The body induction lamp with 433 communication of claim 1, wherein the number of said induction probes is plural.

8. The human body induction light with 433 communication of claim 1, wherein the induction probe further comprises:

the input end of the first key input circuit is connected with the third input end of the first main control circuit;

the first keying input circuit is used for outputting a code matching signal;

the first master control circuit is further used for receiving the code matching signals and controlling the 433 wireless transmitting module to output the code matching signals so as to complete connection between the induction probe and the main lamp panel.

9. The body-sensing lamp with 433 communication of claim 4, wherein the main lamp panel further comprises:

the input end of the second key input circuit is connected with the second input end of the second main control circuit;

the second keying input circuit is used for outputting clear code signals;

and the second master control circuit is also used for receiving the clear code signal and controlling the main lamp panel to be disconnected with the inductive probe.

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